Small-scale Systems
For economic reasons integrated systems usually seek to combine the sustainability of mangrove forest conservation, or rotational forest management systems, with the high income potential from mangrove fisheries or aquaculture. One traditional form of this concept are the 'tambaks' in Indonesia - extensive ponds for trapping and holding fish and shellfish, where strips of mangrove forest are retained on higher ground within the ponds and trees are planted around the dykes to provide soil stability, shade and a source of organic enrichment (via leaf detritus) to the ponds. Originally these tambaks were created in northern Java for milkfish, with shrimp and crabs trapped as a secondary crop (described by Schuster, 19??). Tambaks are now found throughout Indonesia and they are principally specialised for shrimp farming, especially in Sulawesi. However because of over expansion of tambaks, and other forms of coastal habitat development, the relative areas of mangroves to ponds has declined to a point where their natural productivity is extremely low. Since the loss of mangrove resources also affects their function as nursery sites for juvenile fish and shellfish, wild shrimp fry are now much rarer, making it necessary for tambak operators to switch towards hatchery produced post larvae. The latter are generally regarded as being 'weaker' than wild fry and consequently survival rates and production are often poor (Sulawesi, personal observation).
In Indonesia a modern development from the tambak concept is 'tambak tumpang sari' or 'pond forest' (described by Sukardjo, 199*). This integrated system developed on the northern coast of west Java in the 1980s as a response to the problems of lack of income opportunities for poor coastal communities. Due to coastal erosion caused by mangrove degradation, the State Forestry Corporation undertook reforestation using Rhizophora species. Behind the protective mangrove zone, bunded fishponds were constructed with mangrove trees planted as seedlings in the elevated the central part (Fig. 2). A main canal with a water gate allowed water exchange in the pond; the pond itself had a sluice gate and fish ditches around and across the pond bottom to create a good environment for aquaculture.
In the first phase of implementation (3 to 5 years) this system operated as a conventional pond; it was enriched by adding mangroves leaves as a manure. Fish and shrimp entered via the supply canal, then could be harvested virtually on a daily basis in small quantities once the pond biomass had built up. By the second phase (5 to 10 years) growth of the central mangrove had created a forest of saplings or small trees about 5 m tall. At this point the Forest Corporation could begin some exploitation of the mangrove resource as the species planted (Rhizophora) has high economic value for fuelwood and poles.
It should be noted that under this modern Indonesian system, the local people did not own the land or fishponds, but were simply employed by the government agency to undertake the mangrove planting. This generated the equivalent of 4000 man days of work for each hectare of tumpang sari developed (Sukardjo, 199*). By including the aquaculture component, local poor people also benefited from a significant income from aquatic products for 3-5 years until the forest had developed. By this point conditions in the pond for aquaculture had declined because of crowding by the trees and an increase in fish predators (e.g. birds and otters) and pest species.
Although improvements to the management of the system are required in order to increase the longer term benefits from mangrove fisheries, the concept is believed to be sound and a possible model for wider adoption in Indonesia (Sukardjo and Toro, 1987). More realistically, it provides temporary employment and income for some local people, and for the Forestry Corporation an efficient means of reforesting degraded coastal mangroves, but it does not create community ownership and management of the resource. After five years the fishermen cannot buy the fishponds (and the mangrove forest is the property of the Forestry Corporation), although some improvement in coastal fish catches may be expected.
The integration of mangrove forestry with aquaculture is also being tried in Vietnam and Malaysia using crab rearing as the principal income generating activity. In this case the natural mangrove topography is retained by simply fencing off a small area of forest to create a 'crab pen'. The central mangrove area provides a natural habitat for Scylla serrata which are bought from traditional fishermen, stocked in the pens, and fed trash fish. In Sematan, Sarawak a small number of fishermen owners are operating crab pens successfully in this way (personal observation). Although it is too early to state what the long term sustainability will be, the economic returns are good (after six or seven months in the ponds the crabs are exported to Singapore). The method is certainly more integrated than conventional crab ponds, since there is the minimum of disruption to the mangrove forest or soil topography. Because the fences are wooden (mangrove saplings or bamboo), there is a natural tidal exchange through the pens. Some thinning of the central mangrove (to extract poles and firewood) and replanting with seedlings could be developed in this type of forestry-aquaculture system.
Large-scale Systems
There are few examples of large-scale mangrove forestry-fisheries management systems, but several tropical countries are attempting to introduce the concept of 'zoning', whereby areas of mangrove forest are conserved to provide buffer zones for coastal protection and fisheries support, while forest exploitation, aquaculture development, or other economic activities, are being confined to the inner mangrove zone and to coastal land above the intertidal zone.
In Thailand, for example, the problems of poor coastal water quality associated with waste accumulation from intensive shrimp farms has prompted a ban on shrimp farm development on mangrove land. Instead, shrimp farmers are being encouraged to construct ponds behind the mangrove zone so that the latter can serve as a natural biological filter to improve water quality before it reaches the ponds. In the largest mangrove area in Thailand, the Ranong ecosystem, areas of concession forest awarded to charcoal producers are gradually being taken back under the direct control of the Royal Thai Forest Department. The mangroves will then be managed as conservation forest in recognition of their greater value to fisheries and coastal protection. It is also of benefit to the many shrimp farms which are being built in land immediately behind this extensive mangrove delta. Since Ranong is the wettest region of Thailand (Macintosh et al, 1991), particular importance is attached to the value of the mangroves to trap sediments and reduce erosion.
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